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While I'm here remove teh readback test since it doesn't work.
| author | Daniel O'Connor <darius@dons.net.au> |
|---|---|
| date | Sun, 14 Apr 2013 14:26:46 +0930 |
| parents | c59513fd84fb |
| children |
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/** ****************************************************************************** * @file stm32100e_eval_ioe.c * @author MCD Application Team * @version V4.5.0 * @date 07-March-2011 * @brief This file includes the IO Expander driver for STMPE811 IO Expander * devices. ****************************************************************************** * @attention * * THE PRESENT FIRMWARE WHICH IS FOR GUIDANCE ONLY AIMS AT PROVIDING CUSTOMERS * WITH CODING INFORMATION REGARDING THEIR PRODUCTS IN ORDER FOR THEM TO SAVE * TIME. AS A RESULT, STMICROELECTRONICS SHALL NOT BE HELD LIABLE FOR ANY * DIRECT, INDIRECT OR CONSEQUENTIAL DAMAGES WITH RESPECT TO ANY CLAIMS ARISING * FROM THE CONTENT OF SUCH FIRMWARE AND/OR THE USE MADE BY CUSTOMERS OF THE * CODING INFORMATION CONTAINED HEREIN IN CONNECTION WITH THEIR PRODUCTS. * * <h2><center>© COPYRIGHT 2011 STMicroelectronics</center></h2> ****************************************************************************** */ /* File Info : --------------------------------------------------------------- Note: ----- - This driver uses the DMA method for sending and receiving data on I2C bus which allow higher efficiency and reliability of the communication. SUPPORTED FEATURES: - Touch Screen Features: Single point mode (Polling/Interrupt). - TempSensor Feature: accuracy not determined (Polling). - IO Read/write : Set/Reset and Read (Polling/Interrupt). UNSUPPORTED FEATURES: - Row ADC Feature is not supported (not implemented on STM32100E-EVAL board) - Joystick: config and Read (Polling/Interrupt) ----------------------------------------------------------------------------*/ /* Includes ------------------------------------------------------------------*/ #include "stm32100e_eval_ioe.h" /** @addtogroup Utilities * @{ */ /** @addtogroup STM32_EVAL * @{ */ /** @addtogroup STM32100E_EVAL * @{ */ /** @defgroup STM32100E_EVAL_IOE * @brief This file includes the IO Expander driver for STMPE811 IO Expander * devices. * @{ */ /** @defgroup STM32100E_EVAL_IOE_Private_TypesDefinitions * @{ */ /** * @} */ /** @defgroup STM32100E_EVAL_IOE_Private_Defines * @{ */ #define TIMEOUT_MAX 0x1000 /*<! The value of the maximal timeout for I2C waiting loops */ /** * @} */ /** @defgroup STM32100E_EVAL_IOE_Private_Macros * @{ */ /** * @} */ /** @defgroup STM32100E_EVAL_IOE_Private_Variables * @{ */ TS_STATE TS_State; /*<! The global structure holding the TS state */ uint32_t IOE_TimeOut = TIMEOUT_MAX; /*<! Value of Timeout when I2C communication fails */ /** * @} */ /** @defgroup STM32100E_EVAL_IOE_Private_FunctionPrototypes * @{ */ static uint16_t IOE_TS_Read_X(void); static uint16_t IOE_TS_Read_Y(void); static uint16_t IOE_TS_Read_Z(void); static void IOE_GPIO_Config(void); static void IOE_I2C_Config(void); static void IOE_DMA_Config(IOE_DMADirection_TypeDef Direction, uint8_t* buffer); static void IOE_EXTI_Config(void); #ifndef USE_Delay static void delay(__IO uint32_t nCount); #endif /* USE_Delay*/ /** * @} */ /** @defgroup STM32100E_EVAL_IOE_Private_Functions * @{ */ /** * @brief Initializes and Configures the IO_Expanders Functionalities * (Touch Screen ..) and configures all STM32100E-EVAL necessary * hardware (GPIOs, APB clocks ..). * @param None * @retval IOE_OK if all initializations done correctly. Other value if error. */ uint8_t IOE_Config(void) { /* Configure the needed pins */ IOE_GPIO_Config(); /* Configure I2C peripheral */ IOE_I2C_Config(); /* Read IO Expander 1 ID */ if(IOE_IsOperational(IOE_1_ADDR)) { return IOE1_NOT_OPERATIONAL; } /* Generate IOExpander Software reset */ IOE_Reset(IOE_1_ADDR); /* ---------------------- IO Expander configuration --------------------- */ /* Enable the GPIO, Touch Screen and ADC functionalities */ IOE_FnctCmd(IOE_1_ADDR, IOE_TS_FCT | IOE_ADC_FCT | IOE_IO_FCT | IOE_TEMPSENS_FCT , ENABLE); /* Touch Screen controller configuration */ IOE_TS_Config(); /* Temperature Sensor configuration */ IOE_TempSens_Config(); /* ------------------------------------------------------------------------ */ /* Configuration is OK */ return IOE_OK; } /** * @brief Configures The selected interrupts on the IO Expanders. * @param IOE_ITSRC_Source: the source of the interrupts. Could be one or a * combination of the following parameters: * @arg IOE_ITSRC_TSC: Touch Screen interrupts. * @retval IOE_OK: if all initializations are OK. Other value if error. */ uint8_t IOE_ITConfig(uint32_t IOE_ITSRC_Source) { /* Configure the Interrupt output pin to generate low level (INT_CTRL) */ IOE_ITOutConfig(Polarity_Low, Type_Level); /* Manage the Touch Screen Interrupts */ if (IOE_ITSRC_Source & IOE_ITSRC_TSC) { /* Enable the Global interrupt */ IOE_GITCmd(IOE_1_ADDR, ENABLE); /* Enable the Global GPIO Interrupt */ IOE_GITConfig(IOE_1_ADDR, (uint8_t)(IOE_GIT_TOUCH | IOE_GIT_FTH | IOE_GIT_FOV), ENABLE); /* Read the GPIO_IT_STA to clear all pending bits if any */ I2C_ReadDeviceRegister(IOE_1_ADDR, IOE_REG_GPIO_INT_STA); } /* Configure the Interrupt line as EXTI source */ IOE_EXTI_Config(); /* If all OK return IOE_OK */ return IOE_OK; } /** * @brief Writes a bit value to an output IO pin. * @param IO_Pin: The output pin to be set or reset. * IO_Pin_x: Where x can be from 0 to 7. * @param BitVal: The value to be set. This parameter can be one of the * following values: BitSet or BitReset. See IOE_BitVal_TypeDef. * @retval IOE_OK or PARAM_ERROR */ uint8_t IOE_WriteIOPin(uint8_t IO_Pin, IOE_BitValue_TypeDef BitVal) { uint8_t DeviceAddr = 0; /* Get the IO expander Address according to which pin is to be controlled */ if (IO_Pin & IO1_OUT_ALL_PINS) { DeviceAddr = IOE_1_ADDR; } else { return PARAM_ERROR; } /* Apply the bit value to the selected pin */ if (BitVal == BitReset) { /* Set the register */ I2C_WriteDeviceRegister(DeviceAddr, IOE_REG_GPIO_CLR_PIN, IO_Pin); } else { /* Set the register */ I2C_WriteDeviceRegister(DeviceAddr, IOE_REG_GPIO_SET_PIN, IO_Pin); } return IOE_OK; } /** * @brief Returns the status of the selected input IO pin. * @param IO_Pin: The input pin to be read. * IO_Pin_x: Where x can be from 0 to 7. * @arg JOY_IO_PINS: Joystick IO pins (use IOE_JoyStickGetState for these pins) * @retval None */ uint8_t IOE_ReadIOPin(uint32_t IO_Pin) { uint8_t DeviceAddr = 0; uint8_t tmp = 0; if (IO_Pin & IO1_IN_ALL_PINS) { DeviceAddr = IOE_1_ADDR; } else { return PARAM_ERROR; } /* Get all the Pins status */ tmp = I2C_ReadDeviceRegister(DeviceAddr, IOE_REG_GPIO_MP_STA); if ((tmp & (uint8_t)IO_Pin) != 0) { return BitSet; } else { return BitReset; } } /** * @brief Returns Status and positions of the Touch screen. * @param None * @retval Pointer to TS_STATE structure holding Touch Screen information. */ TS_STATE* IOE_TS_GetState(void) { uint32_t xDiff, yDiff , x , y; static uint32_t _x = 0, _y = 0; /* Check if the Touch detect event happenned */ TS_State.TouchDetected = (I2C_ReadDeviceRegister(IOE_1_ADDR, IOE_REG_TSC_CTRL) & 0x80); if(TS_State.TouchDetected) { x = IOE_TS_Read_X(); y = IOE_TS_Read_Y(); xDiff = x > _x? (x - _x): (_x - x); yDiff = y > _y? (y - _y): (_y - y); if (xDiff + yDiff > 5) { _x = x; _y = y; } } /* Update the X position */ TS_State.X = _x; /* Update the Y position */ TS_State.Y = _y; /* Update the Z Pression index */ TS_State.Z = IOE_TS_Read_Z(); /* Clear the interrupt pending bit and enable the FIFO again */ I2C_WriteDeviceRegister(IOE_1_ADDR, IOE_REG_FIFO_STA, 0x01); I2C_WriteDeviceRegister(IOE_1_ADDR, IOE_REG_FIFO_STA, 0x00); /* Return pointer to the updated structure */ return &TS_State; } /** * @brief Returns the temperature row value (in 16 bit format). * @param None * @retval The temperature row value. */ uint32_t IOE_TempSens_GetData(void) { static __IO uint32_t tmp = 0; /* Aquire data enable */ I2C_WriteDeviceRegister(IOE_1_ADDR, IOE_REG_TEMP_CTRL, 0x03); /* Enable the TEMPSENS module */ tmp = (uint32_t)((I2C_ReadDeviceRegister(IOE_1_ADDR, IOE_REG_TEMP_DATA) & 0x03) << 8); tmp |= (uint32_t)I2C_ReadDeviceRegister(IOE_1_ADDR, IOE_REG_TEMP_DATA + 1); tmp = (uint32_t)((33 * tmp * 100) / 751); tmp = (uint32_t)((tmp + 5) / 10); /* return the temprature row value */ return tmp; } /** * @brief Checks the selected Global interrupt source pending bit * @param DeviceAddr: The address of the IOExpander, could be : IOE_1_ADDR. * @param Global_IT: the Global interrupt source to be checked, could be: * @arg Global_IT_GPIO : All IOs interrupt * @arg Global_IT_ADC : ADC interrupt * @arg Global_IT_TEMP : Temperature Sensor interrupts * @arg Global_IT_FE : Touch Screen Controller FIFO Error interrupt * @arg Global_IT_FF : Touch Screen Controller FIFO Full interrupt * @arg Global_IT_FOV : Touch Screen Controller FIFO Overrun interrupt * @arg Global_IT_FTH : Touch Screen Controller FIFO Threshold interrupt * @arg Global_IT_TOUCH : Touch Screen Controller Touch Detected interrupt * @retval Status of the checked flag. Could be SET or RESET. */ FlagStatus IOE_GetGITStatus(uint8_t DeviceAddr, uint8_t Global_IT) { __IO uint8_t tmp = 0; /* get the Interrupt status */ tmp = I2C_ReadDeviceRegister(DeviceAddr, IOE_REG_INT_STA); if ((tmp & (uint8_t)Global_IT) != 0) { return SET; } else { return RESET; } } /** * @brief Clears the selected Global interrupt pending bit(s) * @param DeviceAddr: The address of the IOExpander, could be : IOE_1_ADDR. * @param Global_IT: the Global interrupt to be cleared, could be any combination * of the following values: * @arg Global_IT_GPIO : All IOs interrupt * @arg Global_IT_ADC : ADC interrupt * @arg Global_IT_TEMP : Temperature Sensor interrupts * @arg Global_IT_FE : Touch Screen Controller FIFO Error interrupt * @arg Global_IT_FF : Touch Screen Controller FIFO Full interrupt * @arg Global_IT_FOV : Touch Screen Controller FIFO Overrun interrupt * @arg Global_IT_FTH : Touch Screen Controller FIFO Threshold interrupt * @arg Global_IT_TOUCH : Touch Screen Controller Touch Detected interrupt * @retval IOE_OK: if all initializations are OK. Other value if error. */ uint8_t IOE_ClearGITPending(uint8_t DeviceAddr, uint8_t Global_IT) { /* Write 1 to the bits that have to be cleared */ I2C_WriteDeviceRegister(DeviceAddr, IOE_REG_INT_STA, Global_IT); /* If all OK return IOE_OK */ return IOE_OK; } /** * @brief Checks the status of the selected IO interrupt pending bit * @param DeviceAddr: The address of the IOExpander, could be : IOE_1_ADDR. * @param IO_IT: the IO interrupt to be checked could be IO_ITx Where x can be * from 0 to 7. * @retval Status of the checked flag. Could be SET or RESET. */ FlagStatus IOE_GetIOITStatus(uint8_t DeviceAddr, uint8_t IO_IT) { uint8_t tmp = 0; /* get the Interrupt status */ tmp = I2C_ReadDeviceRegister(DeviceAddr, IOE_REG_GPIO_INT_STA); if ((tmp & (uint8_t)IO_IT) != 0) { return SET; } else { return RESET; } } /** * @brief Clears the selected IO interrupt pending bit(s). * @param DeviceAddr: The address of the IOExpander, could be : IOE_1_ADDR. * @param IO_IT: the IO interrupt to be checked could be IO_ITx Where x can be * from 0 to 7. * @retval IOE_OK: if all initializations are OK. Other value if error. */ uint8_t IOE_ClearIOITPending(uint8_t DeviceAddr, uint8_t IO_IT) { /* Write 1 to the bits that have to be cleared */ I2C_WriteDeviceRegister(DeviceAddr, IOE_REG_GPIO_INT_STA, IO_IT); /* Clear the Edge detection pending bit*/ I2C_WriteDeviceRegister(DeviceAddr, IOE_REG_GPIO_ED, IO_IT); /* Clear the Rising edge pending bit */ I2C_WriteDeviceRegister(DeviceAddr, IOE_REG_GPIO_RE, IO_IT); /* Clear the Falling edge pending bit */ I2C_WriteDeviceRegister(DeviceAddr, IOE_REG_GPIO_FE, IO_IT); return IOE_OK; } /** * @brief Checks if the selected device is correctly configured and * communicates correctly ont the I2C bus. * @param DeviceAddr: The address of the IOExpander, could be : IOE_1_ADDR. * @retval IOE_OK if IOE is operational. Other value if failure. */ uint8_t IOE_IsOperational(uint8_t DeviceAddr) { /* Return Error if the ID is not correct */ if( IOE_ReadID(DeviceAddr) != (uint16_t)STMPE811_ID ) { /* Check if a Timeout occured */ if (IOE_TimeOut == 0) { return(IOE_TimeoutUserCallback()); } else { return IOE_FAILURE; /* ID is not Correct */ } } else { return IOE_OK; /* ID is correct */ } } /** * @brief Resets the IO Expander by Software (SYS_CTRL1, RESET bit). * @param DeviceAddr: The address of the IOExpander, could be : IOE_1_ADDR. * @retval IOE_OK: if all initializations are OK. Other value if error. */ uint8_t IOE_Reset(uint8_t DeviceAddr) { /* Power Down the IO_Expander */ I2C_WriteDeviceRegister(DeviceAddr, IOE_REG_SYS_CTRL1, 0x02); /* wait for a delay to insure registers erasing */ _delay_(2); /* Power On the Codec after the power off => all registers are reinitialized*/ I2C_WriteDeviceRegister(DeviceAddr, IOE_REG_SYS_CTRL1, 0x00); /* If all OK return IOE_OK */ return IOE_OK; } /** * @brief Reads the selected device's ID. * @param DeviceAddr: The address of the IOExpander, could be : IOE_1_ADDR. * @retval The Device ID (two bytes). */ uint16_t IOE_ReadID(uint8_t DeviceAddr) { uint16_t tmp = 0; /* Read device ID */ tmp = I2C_ReadDeviceRegister(DeviceAddr, 0); tmp = (uint32_t)(tmp << 8); tmp |= (uint32_t)I2C_ReadDeviceRegister(DeviceAddr, 1); /* Return the ID */ return (uint16_t)tmp; } /** * @brief Configures the selcted IO Expander functionalities. * @param DeviceAddr: The address of the IOExpander, could be : IOE_1_ADDR. * @param Fct: the functions to be configured. could be any * combination of the following values: * @arg IOE_IO_FCT : IO function * @arg IOE_TS_FCT : Touch Screen function * @arg IOE_ADC_FCT : ADC function * @arg IOE_TEMPSENS_FCT : Tempreature Sensor function * @retval IOE_OK: if all initializations are OK. Other value if error. */ uint8_t IOE_FnctCmd(uint8_t DeviceAddr, uint8_t Fct, FunctionalState NewState) { uint8_t tmp = 0; /* Get the register value */ tmp = I2C_ReadDeviceRegister(DeviceAddr, IOE_REG_SYS_CTRL2); if (NewState != DISABLE) { /* Set the Functionalities to be Enabled */ tmp &= ~(uint8_t)Fct; } else { /* Set the Functionalities to be Disabled */ tmp |= (uint8_t)Fct; } /* Set the register value */ I2C_WriteDeviceRegister(DeviceAddr, IOE_REG_SYS_CTRL2, tmp); /* If all OK return IOE_OK */ return IOE_OK; } /** * @brief Configures the selected pin direction (to be an input or an output) * @param DeviceAddr: The address of the IOExpander, could be : IOE_1_ADDR. * @param IO_Pin: IO_Pin_x: Where x can be from 0 to 7. * @param Direction: could be Direction_IN or Direction_OUT. * @retval IOE_OK: if all initializations are OK. Other value if error. */ uint8_t IOE_IOPinConfig(uint8_t DeviceAddr, uint8_t IO_Pin, uint8_t Direction) { uint8_t tmp = 0; /* Get all the Pins direction */ tmp = I2C_ReadDeviceRegister(DeviceAddr, IOE_REG_GPIO_DIR); if (Direction != Direction_IN) { tmp |= (uint8_t)IO_Pin; } else { tmp &= ~(uint8_t)IO_Pin; } /* Write the register new value */ I2C_WriteDeviceRegister(DeviceAddr, IOE_REG_GPIO_DIR, tmp); /* If all OK return IOE_OK */ return IOE_OK; } /** * @brief Enables or disables the Global interrupt. * @param DeviceAddr: The address of the IOExpander, could be :I OE_1_ADDR. * @param NewState: could be ENABLE or DISABLE. * @retval IOE_OK: if all initializations are OK. Other value if error. */ uint8_t IOE_GITCmd(uint8_t DeviceAddr, FunctionalState NewState) { uint8_t tmp = 0; /* Read the Interrupt Control register */ I2C_ReadDeviceRegister(DeviceAddr, IOE_REG_INT_CTRL); if (NewState != DISABLE) { /* Set the global interrupts to be Enabled */ tmp |= (uint8_t)IOE_GIT_EN; } else { /* Set the global interrupts to be Disabled */ tmp &= ~(uint8_t)IOE_GIT_EN; } /* Write Back the Interrupt Control register */ I2C_WriteDeviceRegister(DeviceAddr, IOE_REG_INT_CTRL, tmp); /* If all OK return IOE_OK */ return IOE_OK; } /** * @brief Configures the selected source to generate or not a global interrupt * @param DeviceAddr: The address of the IOExpander, could be : IOE_1_ADDR * @param Global_IT: the interrupt source to be configured, could be: * @arg Global_IT_GPIO : All IOs interrupt * @arg Global_IT_ADC : ADC interrupt * @arg Global_IT_TEMP : Temperature Sensor interrupts * @arg Global_IT_FE : Touch Screen Controller FIFO Error interrupt * @arg Global_IT_FF : Touch Screen Controller FIFO Full interrupt * @arg Global_IT_FOV : Touch Screen Controller FIFO Overrun interrupt * @arg Global_IT_FTH : Touch Screen Controller FIFO Threshold interrupt * @arg Global_IT_TOUCH : Touch Screen Controller Touch Detected interrupt * @retval IOE_OK: if all initializations are OK. Other value if error. */ uint8_t IOE_GITConfig(uint8_t DeviceAddr, uint8_t Global_IT, FunctionalState NewState) { uint8_t tmp = 0; /* Get the current value of the INT_EN register */ tmp = I2C_ReadDeviceRegister(DeviceAddr, IOE_REG_INT_EN); if (NewState != DISABLE) { /* Set the interrupts to be Enabled */ tmp |= (uint8_t)Global_IT; } else { /* Set the interrupts to be Disabled */ tmp &= ~(uint8_t)Global_IT; } /* Set the register */ I2C_WriteDeviceRegister(DeviceAddr, IOE_REG_INT_EN, tmp); /* If all OK return IOE_OK */ return IOE_OK; } /** * @brief Configures the selected pins to generate an interrupt or not. * @param DeviceAddr: The address of the IOExpander, could be : IOE_1_ADDR. * @param IO_IT: The IO interrupt to be configured. This parameter could be any * combination of the following values: * @arg IO_IT_x: where x can be from 0 to 7. * @param NewState: could be ENABLE or DISABLE. * @retval IOE_OK: if all initializations are OK. Other value if error. */ uint8_t IOE_IOITConfig(uint8_t DeviceAddr, uint8_t IO_IT, FunctionalState NewState) { uint8_t tmp = 0; tmp = I2C_ReadDeviceRegister(DeviceAddr, IOE_REG_GPIO_INT_EN); if (NewState != DISABLE) { /* Set the interrupts to be Enabled */ tmp |= (uint8_t)IO_IT; } else { /* Set the interrupts to be Disabled */ tmp &= ~(uint8_t)IO_IT; } /* Set the register */ I2C_WriteDeviceRegister(DeviceAddr, IOE_REG_GPIO_INT_EN, tmp); /* If all OK return IOE_OK */ return IOE_OK; } /** * @brief Configures the touch Screen Controller (Single point detection) * @param None * @retval IOE_OK if all initializations are OK. Other value if error. */ uint8_t IOE_TS_Config(void) { uint8_t tmp = 0; /* Enable TSC Fct: already done in IOE_Config */ tmp = I2C_ReadDeviceRegister(IOE_1_ADDR, IOE_REG_SYS_CTRL2); tmp &= ~(uint32_t)(IOE_TS_FCT | IOE_ADC_FCT); I2C_WriteDeviceRegister(IOE_1_ADDR, IOE_REG_SYS_CTRL2, tmp); /* Enable the TSC gloabl interrupts */ tmp = I2C_ReadDeviceRegister(IOE_1_ADDR, IOE_REG_INT_EN); tmp |= (uint32_t)(IOE_GIT_TOUCH | IOE_GIT_FTH | IOE_GIT_FOV); I2C_WriteDeviceRegister(IOE_1_ADDR, IOE_REG_INT_EN, tmp); /* Select Sample Time, bit number and ADC Reference */ I2C_WriteDeviceRegister(IOE_1_ADDR, IOE_REG_ADC_CTRL1, 0x49); /* Wait for ~20 ms */ _delay_(2); /* Select the ADC clock speed: 3.25 MHz */ I2C_WriteDeviceRegister(IOE_1_ADDR, IOE_REG_ADC_CTRL2, 0x01); /* Select TSC pins in non default mode */ tmp = I2C_ReadDeviceRegister(IOE_1_ADDR, IOE_REG_GPIO_AF); tmp &= ~(uint8_t)TOUCH_IO_ALL; I2C_WriteDeviceRegister(IOE_1_ADDR, IOE_REG_GPIO_AF, tmp); /* Select 2 nF filter capacitor */ I2C_WriteDeviceRegister(IOE_1_ADDR, IOE_REG_TSC_CFG, 0x9A); /* Select single point reading */ I2C_WriteDeviceRegister(IOE_1_ADDR, IOE_REG_FIFO_TH, 0x01); /* Write 0x01 to clear the FIFO memory content. */ I2C_WriteDeviceRegister(IOE_1_ADDR, IOE_REG_FIFO_STA, 0x01); /* Write 0x00 to put the FIFO back into operation mode */ I2C_WriteDeviceRegister(IOE_1_ADDR, IOE_REG_FIFO_STA, 0x00); /* set the data format for Z value: 7 fractional part and 1 whole part */ I2C_WriteDeviceRegister(IOE_1_ADDR, IOE_REG_TSC_FRACT_XYZ, 0x01); /* set the driving capability of the device for TSC pins: 50mA */ I2C_WriteDeviceRegister(IOE_1_ADDR, IOE_REG_TSC_I_DRIVE, 0x01); /* Use no tracking index, touchscreen controller operation mode (XYZ) and enable the TSC */ I2C_WriteDeviceRegister(IOE_1_ADDR, IOE_REG_TSC_CTRL, 0x01); /* Clear all the status pending bits */ I2C_WriteDeviceRegister(IOE_1_ADDR, IOE_REG_INT_STA, 0xFF); /* Initialize the TS structure to their default values */ TS_State.TouchDetected = TS_State.X = TS_State.Y = TS_State.Z = 0; /* All configuration done */ return IOE_OK; } /** * @brief Configures and enables the Temperature sensor module. * @param None * @retval IOE_OK if all initializations are OK. Other value if error. */ uint8_t IOE_TempSens_Config(void) { __IO uint8_t tmp = 0; /* Enable Temperature Sensor Fct: already done in IOE_Config */ tmp = I2C_ReadDeviceRegister(IOE_1_ADDR, IOE_REG_SYS_CTRL2); tmp &= ~(uint32_t)(IOE_TEMPSENS_FCT | IOE_ADC_FCT); I2C_WriteDeviceRegister(IOE_1_ADDR, IOE_REG_SYS_CTRL2, tmp); /* Enable the TEMPSENS module */ I2C_WriteDeviceRegister(IOE_1_ADDR, IOE_REG_TEMP_CTRL, 0x01); /* Aquire data enable */ I2C_WriteDeviceRegister(IOE_1_ADDR, IOE_REG_TEMP_CTRL, 0x3); /* All configuration done */ return IOE_OK; } /** * @brief Configures the selected pin to be in Alternate function or not * @param DeviceAddr: The address of the IOExpander, could be : IOE_1_ADDR. * @param IO_Pin: IO_Pin_x, Where x can be from 0 to 7. * @param NewState: State of the AF for the selected pin, could be * ENABLE or DISABLE. * @retval IOE_OK: if all initializations are OK. Other value if error. */ uint8_t IOE_IOAFConfig(uint8_t DeviceAddr, uint8_t IO_Pin, FunctionalState NewState) { uint8_t tmp = 0; /* Get the current state of the GPIO_AF register */ tmp = I2C_ReadDeviceRegister(DeviceAddr, IOE_REG_GPIO_AF); if (NewState != DISABLE) { /* Enable the selected pins alternate function */ tmp |= (uint8_t)IO_Pin; } else { /* Disable the selected pins alternate function */ tmp &= ~(uint8_t)IO_Pin; } /* Write back the new valu in GPIO_AF register */ I2C_WriteDeviceRegister(DeviceAddr, IOE_REG_GPIO_AF, tmp); /* If all OK return IOE_OK */ return IOE_OK; } /** * @brief Configures the Edge for which a transition is detectable for the * the selected pin. * @param DeviceAddr: The address of the IOExpander, could be : IOE_1_ADDR. * @param IO_Pin: IO_Pin_x, Where x can be from 0 to 7. * @param Edge: The edge which will be detected. This parameter can be one or a * a combination of follwing values: EDGE_FALLING and EDGE_RISING . * @retval IOE_OK: if all initializations are OK. Other value if error. */ uint8_t IOE_IOEdgeConfig(uint8_t DeviceAddr, uint8_t IO_Pin, uint8_t Edge) { uint8_t tmp1 = 0, tmp2 = 0; /* Get the registers values */ tmp1 = I2C_ReadDeviceRegister(DeviceAddr, IOE_REG_GPIO_FE); tmp2 = I2C_ReadDeviceRegister(DeviceAddr, IOE_REG_GPIO_RE); /* Disable the Falling Edge */ tmp1 &= ~(uint8_t)IO_Pin; /* Disable the Falling Edge */ tmp2 &= ~(uint8_t)IO_Pin; /* Enable the Falling edge if selected */ if (Edge & EDGE_FALLING) { tmp1 |= (uint8_t)IO_Pin; } /* Enable the Rising edge if selected */ if (Edge & EDGE_RISING) { tmp2 |= (uint8_t)IO_Pin; } /* Write back the registers values */ I2C_WriteDeviceRegister(DeviceAddr, IOE_REG_GPIO_FE, tmp1); I2C_WriteDeviceRegister(DeviceAddr, IOE_REG_GPIO_RE, tmp2); /* if OK return 0 */ return IOE_OK; } /** * @brief Configures the Interrupt line active state and format (level/edge) * @param Polarity: could be * @arg Polarity_Low: Interrupt line is active Low/Falling edge * @arg Polarity_High: Interrupt line is active High/Rising edge * @param Type: Interrupt line activity type, could be one of the following values * @arg Type_Level: Interrupt line is active in level model * @arg Type_Edge: Interrupt line is active in edge model * @retval IOE_OK: if all initializations are OK. Other value if error. */ uint8_t IOE_ITOutConfig(uint8_t Polarity, uint8_t Type) { uint8_t tmp = 0; /* Get the register IOE_REG_INT_CTRL value */ tmp = I2C_ReadDeviceRegister(IOE_1_ADDR, IOE_REG_INT_CTRL); /* Mask the polarity and type bits */ tmp &= ~(uint8_t)0x06; /* Modify the Interrupt Output line configuration */ tmp |= (uint8_t)(Polarity | Type); /* Set the register */ I2C_WriteDeviceRegister(IOE_1_ADDR, IOE_REG_INT_CTRL, tmp); /* If all OK return IOE_OK */ return IOE_OK; } /** * @brief Writes a value in a register of the device through I2C. * @param DeviceAddr: The address of the IOExpander, could be : IOE_1_ADDR. * @param RegisterAddr: The target register adress * @param RegisterValue: The target register value to be written * @retval IOE_OK: if all operations are OK. Other value if error. */ uint8_t I2C_WriteDeviceRegister(uint8_t DeviceAddr, uint8_t RegisterAddr, uint8_t RegisterValue) { uint32_t read_verif = 0; uint8_t IOE_BufferTX = 0; /* Get Value to be written */ IOE_BufferTX = RegisterValue; /* Configure DMA Peripheral */ IOE_DMA_Config(IOE_DMA_TX, (uint8_t*)(&IOE_BufferTX)); /* Enable the I2C peripheral */ I2C_GenerateSTART(IOE_I2C, ENABLE); /* Test on SB Flag */ IOE_TimeOut = TIMEOUT_MAX; while (I2C_GetFlagStatus(IOE_I2C,I2C_FLAG_SB) == RESET) { if (IOE_TimeOut-- == 0) return(IOE_TimeoutUserCallback()); } /* Transmit the slave address and enable writing operation */ I2C_Send7bitAddress(IOE_I2C, DeviceAddr, I2C_Direction_Transmitter); /* Test on ADDR Flag */ IOE_TimeOut = TIMEOUT_MAX; while (!I2C_CheckEvent(IOE_I2C, I2C_EVENT_MASTER_TRANSMITTER_MODE_SELECTED)) { if (IOE_TimeOut-- == 0) return(IOE_TimeoutUserCallback()); } /* Transmit the first address for r/w operations */ I2C_SendData(IOE_I2C, RegisterAddr); /* Test on TXE FLag (data dent) */ IOE_TimeOut = TIMEOUT_MAX; while ((!I2C_GetFlagStatus(IOE_I2C,I2C_FLAG_TXE)) && (!I2C_GetFlagStatus(IOE_I2C,I2C_FLAG_BTF))) { if (IOE_TimeOut-- == 0) return(IOE_TimeoutUserCallback()); } /* Enable I2C DMA request */ I2C_DMACmd(IOE_I2C,ENABLE); /* Enable DMA TX Channel */ DMA_Cmd(IOE_DMA_TX_CHANNEL, ENABLE); /* Wait until DMA Transfer Complete */ IOE_TimeOut = TIMEOUT_MAX; while (!DMA_GetFlagStatus(IOE_DMA_TX_TCFLAG)) { if (IOE_TimeOut-- == 0) return(IOE_TimeoutUserCallback()); } /* Wait until BTF Flag is set before generating STOP */ IOE_TimeOut = 2 * TIMEOUT_MAX; while ((!I2C_GetFlagStatus(IOE_I2C,I2C_FLAG_BTF))) { } /* Send STOP Condition */ I2C_GenerateSTOP(IOE_I2C, ENABLE); /* Disable DMA TX Channel */ DMA_Cmd(IOE_DMA_TX_CHANNEL, DISABLE); /* Disable I2C DMA request */ I2C_DMACmd(IOE_I2C,DISABLE); /* Clear DMA TX Transfer Complete Flag */ DMA_ClearFlag(IOE_DMA_TX_TCFLAG); #ifdef VERIFY_WRITTENDATA /* Verify (if needed) that the loaded data is correct */ /* Read the just written register*/ read_verif = I2C_ReadDeviceRegister(DeviceAddr, RegisterAddr); /* Load the register and verify its value */ if (read_verif != RegisterValue) { /* Control data wrongly tranfered */ read_verif = IOE_FAILURE; } else { /* Control data correctly transfered */ read_verif = 0; } #endif /* Return the verifying value: 0 (Passed) or 1 (Failed) */ return read_verif; } /** * @brief Reads a register of the device through I2C. * @param DeviceAddr: The address of the device, could be : IOE_1_ADDR. * @param RegisterAddr: The target register adress (between 00x and 0x24) * @retval The value of the read register (0xAA if Timout occured) */ uint8_t I2C_ReadDeviceRegister(uint8_t DeviceAddr, uint8_t RegisterAddr) { uint8_t IOE_BufferRX[2] = {0x00, 0x00}; /* Configure DMA Peripheral */ IOE_DMA_Config(IOE_DMA_RX, (uint8_t*)IOE_BufferRX); /* Enable DMA NACK automatic generation */ I2C_DMALastTransferCmd(IOE_I2C, ENABLE); /* Enable the I2C peripheral */ I2C_GenerateSTART(IOE_I2C, ENABLE); /* Test on SB Flag */ IOE_TimeOut = TIMEOUT_MAX; while (!I2C_GetFlagStatus(IOE_I2C,I2C_FLAG_SB)) { if (IOE_TimeOut-- == 0) return(IOE_TimeoutUserCallback()); } /* Send device address for write */ I2C_Send7bitAddress(IOE_I2C, DeviceAddr, I2C_Direction_Transmitter); /* Test on ADDR Flag */ IOE_TimeOut = TIMEOUT_MAX; while (!I2C_CheckEvent(IOE_I2C, I2C_EVENT_MASTER_TRANSMITTER_MODE_SELECTED)) { if (IOE_TimeOut-- == 0) return(IOE_TimeoutUserCallback()); } /* Send the device's internal address to write to */ I2C_SendData(IOE_I2C, RegisterAddr); /* Test on TXE FLag (data dent) */ IOE_TimeOut = TIMEOUT_MAX; while ((!I2C_GetFlagStatus(IOE_I2C,I2C_FLAG_TXE)) && (!I2C_GetFlagStatus(IOE_I2C,I2C_FLAG_BTF))) { if (IOE_TimeOut-- == 0) return(IOE_TimeoutUserCallback()); } /* Send START condition a second time */ I2C_GenerateSTART(IOE_I2C, ENABLE); /* Test on SB Flag */ IOE_TimeOut = TIMEOUT_MAX; while (!I2C_GetFlagStatus(IOE_I2C,I2C_FLAG_SB)) { if (IOE_TimeOut-- == 0) return(IOE_TimeoutUserCallback()); } /* Send IOExpander address for read */ I2C_Send7bitAddress(IOE_I2C, DeviceAddr, I2C_Direction_Receiver); /* Test on ADDR Flag */ IOE_TimeOut = TIMEOUT_MAX; while (!I2C_CheckEvent(IOE_I2C, I2C_EVENT_MASTER_RECEIVER_MODE_SELECTED)) { if (IOE_TimeOut-- == 0) return(IOE_TimeoutUserCallback()); } /* Enable I2C DMA request */ I2C_DMACmd(IOE_I2C,ENABLE); /* Enable DMA RX Channel */ DMA_Cmd(IOE_DMA_RX_CHANNEL, ENABLE); /* Wait until DMA Transfer Complete */ IOE_TimeOut = 2 * TIMEOUT_MAX; while (!DMA_GetFlagStatus(IOE_DMA_RX_TCFLAG)) { if (IOE_TimeOut-- == 0) return(IOE_TimeoutUserCallback()); } /* Send STOP Condition */ I2C_GenerateSTOP(IOE_I2C, ENABLE); /* Disable DMA RX Channel */ DMA_Cmd(IOE_DMA_RX_CHANNEL, DISABLE); /* Disable I2C DMA request */ I2C_DMACmd(IOE_I2C,DISABLE); /* Clear DMA RX Transfer Complete Flag */ DMA_ClearFlag(IOE_DMA_RX_TCFLAG); /* return a pointer to the IOE_Buffer */ return (uint8_t)IOE_BufferRX[0]; } /** * @brief Reads a buffer of 2 bytes from the device registers. * @param DeviceAddr: The address of the device, could be : IOE_1_ADDR. * @param RegisterAddr: The target register adress (between 00x and 0x24) * @retval A pointer to the buffer containing the two returned bytes (in halfword). */ uint16_t I2C_ReadDataBuffer(uint8_t DeviceAddr, uint32_t RegisterAddr) { uint8_t tmp= 0; uint8_t IOE_BufferRX[2] = {0x00, 0x00}; /* Configure DMA Peripheral */ IOE_DMA_Config(IOE_DMA_RX, (uint8_t*)IOE_BufferRX); /* Enable DMA NACK automatic generation */ I2C_DMALastTransferCmd(IOE_I2C, ENABLE); /* Enable the I2C peripheral */ I2C_GenerateSTART(IOE_I2C, ENABLE); /* Test on SB Flag */ IOE_TimeOut = TIMEOUT_MAX; while (!I2C_GetFlagStatus(IOE_I2C,I2C_FLAG_SB)) { if (IOE_TimeOut-- == 0) return(IOE_TimeoutUserCallback()); } /* Send device address for write */ I2C_Send7bitAddress(IOE_I2C, DeviceAddr, I2C_Direction_Transmitter); /* Test on ADDR Flag */ IOE_TimeOut = TIMEOUT_MAX; while (!I2C_CheckEvent(IOE_I2C, I2C_EVENT_MASTER_TRANSMITTER_MODE_SELECTED)) { if (IOE_TimeOut-- == 0) return(IOE_TimeoutUserCallback()); } /* Send the device's internal address to write to */ I2C_SendData(IOE_I2C, RegisterAddr); /* Test on TXE FLag (data dent) */ IOE_TimeOut = TIMEOUT_MAX; while ((!I2C_GetFlagStatus(IOE_I2C,I2C_FLAG_TXE)) && (!I2C_GetFlagStatus(IOE_I2C,I2C_FLAG_BTF))) { if (IOE_TimeOut-- == 0) return(IOE_TimeoutUserCallback()); } /* Send START condition a second time */ I2C_GenerateSTART(IOE_I2C, ENABLE); /* Test on SB Flag */ IOE_TimeOut = TIMEOUT_MAX; while (!I2C_GetFlagStatus(IOE_I2C,I2C_FLAG_SB)) { if (IOE_TimeOut-- == 0) return(IOE_TimeoutUserCallback()); } /* Send IOExpander address for read */ I2C_Send7bitAddress(IOE_I2C, DeviceAddr, I2C_Direction_Receiver); /* Test on ADDR Flag */ IOE_TimeOut = TIMEOUT_MAX; while (!I2C_CheckEvent(IOE_I2C, I2C_EVENT_MASTER_RECEIVER_MODE_SELECTED)) { if (IOE_TimeOut-- == 0) return(IOE_TimeoutUserCallback()); } /* Enable I2C DMA request */ I2C_DMACmd(IOE_I2C,ENABLE); /* Enable DMA RX Channel */ DMA_Cmd(IOE_DMA_RX_CHANNEL, ENABLE); /* Wait until DMA Transfer Complete */ IOE_TimeOut = 2 * TIMEOUT_MAX; while (!DMA_GetFlagStatus(IOE_DMA_RX_TCFLAG)) { if (IOE_TimeOut-- == 0) return(IOE_TimeoutUserCallback()); } /* Send STOP Condition */ I2C_GenerateSTOP(IOE_I2C, ENABLE); /* Disable DMA RX Channel */ DMA_Cmd(IOE_DMA_RX_CHANNEL, DISABLE); /* Disable I2C DMA request */ I2C_DMACmd(IOE_I2C,DISABLE); /* Clear DMA RX Transfer Complete Flag */ DMA_ClearFlag(IOE_DMA_RX_TCFLAG); /* Reorganize received data */ tmp = IOE_BufferRX[0]; IOE_BufferRX[0] = IOE_BufferRX[1]; IOE_BufferRX[1] = tmp; /* return a pointer to the IOE_Buffer */ return *(uint16_t *)IOE_BufferRX; } /** * @brief Return Touch Screen X position value * @param None * @retval X position. */ static uint16_t IOE_TS_Read_X(void) { int32_t x, xr; x = I2C_ReadDataBuffer(IOE_1_ADDR, IOE_REG_TSC_DATA_Y); /* first correction */ xr = (x * 320) >> 12; /* second correction */ xr = ((xr * 32)/29) - 17; if(xr <= 0) xr = 0; return (uint16_t)(xr); } /** * @brief Return Touch Screen Y position value * @param None * @retval Y position. */ static uint16_t IOE_TS_Read_Y(void) { int32_t y, yr; y= I2C_ReadDataBuffer(IOE_1_ADDR, IOE_REG_TSC_DATA_X); yr= (y * 240) >> 12; yr = ((yr * 240) / 217) - 12; if(yr <= 0) yr = 0; return (uint16_t)(yr); } /** * @brief Return Touch Screen Z position value * @param None * @retval Z position. */ static uint16_t IOE_TS_Read_Z(void) { uint32_t z; z = I2C_ReadDataBuffer(IOE_1_ADDR, IOE_REG_TSC_DATA_Z); if(z <= 0) z = 0; return (uint16_t)(z); } /** * @brief Initializes the GPIO pins used by the IO expander. * @param None * @retval None */ static void IOE_GPIO_Config(void) { GPIO_InitTypeDef GPIO_InitStructure; /* Enable IOE_I2C and IOE_I2C_PORT & Alternate Function clocks */ RCC_APB1PeriphClockCmd(IOE_I2C_CLK, ENABLE); RCC_APB2PeriphClockCmd(IOE_I2C_SCL_GPIO_CLK | IOE_I2C_SDA_GPIO_CLK | IOE_IT_GPIO_CLK | RCC_APB2Periph_AFIO, ENABLE); /* Reset IOE_I2C IP */ RCC_APB1PeriphResetCmd(IOE_I2C_CLK, ENABLE); /* Release reset signal of IOE_I2C IP */ RCC_APB1PeriphResetCmd(IOE_I2C_CLK, DISABLE); /* IOE_I2C SCL and SDA pins configuration */ GPIO_InitStructure.GPIO_Pin = IOE_I2C_SCL_PIN; GPIO_InitStructure.GPIO_Speed = GPIO_Speed_10MHz; GPIO_InitStructure.GPIO_Mode = GPIO_Mode_AF_OD; GPIO_Init(IOE_I2C_SCL_GPIO_PORT, &GPIO_InitStructure); /* IOE_I2C SCL and SDA pins configuration */ GPIO_InitStructure.GPIO_Pin = IOE_I2C_SDA_PIN; GPIO_Init(IOE_I2C_SDA_GPIO_PORT, &GPIO_InitStructure); /* Set EXTI pin as Input PullUp - IO_Expander_INT */ GPIO_InitStructure.GPIO_Pin = IOE_IT_PIN; GPIO_InitStructure.GPIO_Mode = GPIO_Mode_IPU; GPIO_Init(IOE_IT_GPIO_PORT, &GPIO_InitStructure); /* Connect IO Expander IT line to EXTI line */ GPIO_EXTILineConfig(IOE_IT_EXTI_PORT_SOURCE, IOE_IT_EXTI_PIN_SOURCE); } /** * @brief Configure the I2C Peripheral used to communicate with IO_Expanders. * @param None * @retval None */ static void IOE_I2C_Config(void) { I2C_InitTypeDef I2C_InitStructure; /* IOE_I2C configuration */ I2C_InitStructure.I2C_Mode = I2C_Mode_I2C; I2C_InitStructure.I2C_DutyCycle = I2C_DutyCycle_2; I2C_InitStructure.I2C_OwnAddress1 = 0x00; I2C_InitStructure.I2C_Ack = I2C_Ack_Enable; I2C_InitStructure.I2C_AcknowledgedAddress = I2C_AcknowledgedAddress_7bit; I2C_InitStructure.I2C_ClockSpeed = IOE_I2C_SPEED; I2C_Init(IOE_I2C, &I2C_InitStructure); } /** * @brief Configure the DMA Peripheral used to handle communication via I2C. * @param None * @retval None */ static void IOE_DMA_Config(IOE_DMADirection_TypeDef Direction, uint8_t* buffer) { DMA_InitTypeDef DMA_InitStructure; RCC_AHBPeriphClockCmd(IOE_DMA_CLK, ENABLE); /* Initialize the DMA_PeripheralBaseAddr member */ DMA_InitStructure.DMA_PeripheralBaseAddr = IOE_I2C_DR; /* Initialize the DMA_MemoryBaseAddr member */ DMA_InitStructure.DMA_MemoryBaseAddr = (uint32_t)buffer; /* Initialize the DMA_PeripheralInc member */ DMA_InitStructure.DMA_PeripheralInc = DMA_PeripheralInc_Disable; /* Initialize the DMA_MemoryInc member */ DMA_InitStructure.DMA_MemoryInc = DMA_MemoryInc_Enable; /* Initialize the DMA_PeripheralDataSize member */ DMA_InitStructure.DMA_PeripheralDataSize = DMA_PeripheralDataSize_Byte; /* Initialize the DMA_MemoryDataSize member */ DMA_InitStructure.DMA_MemoryDataSize = DMA_MemoryDataSize_Byte; /* Initialize the DMA_Mode member */ DMA_InitStructure.DMA_Mode = DMA_Mode_Normal; /* Initialize the DMA_Priority member */ DMA_InitStructure.DMA_Priority = DMA_Priority_VeryHigh; /* Initialize the DMA_M2M member */ DMA_InitStructure.DMA_M2M = DMA_M2M_Disable; /* If using DMA for Reception */ if (Direction == IOE_DMA_RX) { /* Initialize the DMA_DIR member */ DMA_InitStructure.DMA_DIR = DMA_DIR_PeripheralSRC; /* Initialize the DMA_BufferSize member */ DMA_InitStructure.DMA_BufferSize = 2; DMA_DeInit(IOE_DMA_RX_CHANNEL); DMA_Init(IOE_DMA_RX_CHANNEL, &DMA_InitStructure); } /* If using DMA for Transmission */ else if (Direction == IOE_DMA_TX) { /* Initialize the DMA_DIR member */ DMA_InitStructure.DMA_DIR = DMA_DIR_PeripheralDST; /* Initialize the DMA_BufferSize member */ DMA_InitStructure.DMA_BufferSize = 1; DMA_DeInit(IOE_DMA_TX_CHANNEL); DMA_Init(IOE_DMA_TX_CHANNEL, &DMA_InitStructure); } } /** * @brief Configures the IO expander Interrupt line and GPIO in EXTI mode. * @param None * @retval None */ static void IOE_EXTI_Config(void) { GPIO_InitTypeDef GPIO_InitStructure; NVIC_InitTypeDef NVIC_InitStructure; EXTI_InitTypeDef EXTI_InitStructure; /* Enable Button GPIO clock */ RCC_APB2PeriphClockCmd(IOE_IT_GPIO_CLK | RCC_APB2Periph_AFIO, ENABLE); /* Configure Button pin as input floating */ GPIO_InitStructure.GPIO_Pin = IOE_IT_PIN; GPIO_InitStructure.GPIO_Mode = GPIO_Mode_IN_FLOATING; GPIO_Init(IOE_IT_GPIO_PORT, &GPIO_InitStructure); /* Connect Button EXTI Line to Button GPIO Pin */ GPIO_EXTILineConfig(IOE_IT_EXTI_PORT_SOURCE, IOE_IT_EXTI_PIN_SOURCE); /* Configure Button EXTI line */ EXTI_InitStructure.EXTI_Line = IOE_IT_EXTI_LINE; EXTI_InitStructure.EXTI_Mode = EXTI_Mode_Interrupt; EXTI_InitStructure.EXTI_Trigger = EXTI_Trigger_Rising_Falling; EXTI_InitStructure.EXTI_LineCmd = ENABLE; EXTI_Init(&EXTI_InitStructure); /* Enable and set Button EXTI Interrupt to the lowest priority */ NVIC_InitStructure.NVIC_IRQChannel = IOE_IT_EXTI_IRQn; NVIC_InitStructure.NVIC_IRQChannelPreemptionPriority = 0x0F; NVIC_InitStructure.NVIC_IRQChannelSubPriority = 0x0F; NVIC_InitStructure.NVIC_IRQChannelCmd = ENABLE; NVIC_Init(&NVIC_InitStructure); } #ifndef USE_Delay /** * @brief Inserts a delay time. * @param nCount: specifies the delay time length. * @retval None */ static void delay(__IO uint32_t nCount) { __IO uint32_t index = 0; for(index = (100000 * nCount); index != 0; index--) { } } #endif /* USE_Delay*/ /** * @} */ /** * @} */ /** * @} */ /** * @} */ /** * @} */ /******************* (C) COPYRIGHT 2011 STMicroelectronics *****END OF FILE****/